Coordination chemistry of bis (. delta.-camphorquinone dioximato

This work was supported by the Scientific. Affairs Division, North Atlantic Treaty Organization. (NATO), through Grant 13 18 and by the Danish Nationa...
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Inorg. Chem. 1980, 19, 3121-3128

In our view the very small C r ( l ) - O ( l ) - C r ( 2 ) bridging angle of 142.8 (5)' as compared with 154-166' reported for the rhodo salts is partially responsible for this difference. A discussion of such relations will be the subject of future publications from our laboratories. Acknowledgment. We are very grateful to Mrs. Solveig Kallesere, who performed most of the susceptibility rneasurements, and to Ms. Suzanne Byrd and Ms. Shaina Virji for 1y.12J3J5J6343144

(43) Flint, C. D.; Greenough, P. J. Chem. SOC., Faraday Trans. 2 1973,69, 1469. (44) Gudel, H. U.; Furrer, A. Mol. Phys. 1977, 33, 1335.

3121

assistance in the collection and reduction of the crystallographic data. This work was supported by the Scientific Affairs Division, North Atlantic Treaty O r g a n i z a t i o n ( N A T O ) , through Grant 13 18 and by the Danish National Science Research Council through Grant 5 11-3993. Registry No. [(NH,),Cr(OH)Cr(NH3)slC1,, 15007-47-3; cis-

[(NH3)~Cr(OH)Cr(NH3)4(OH)](S20s)2~3H20, 74410-09-6; cis[(NH3)5Cr(OH)Cr(NH3)4(OH)]C14, 74365-64-3. Supplementary Material Available: A table of anisotropic thermal parameters and a list of observed and calculated structure amplitudes (electrons X 10) (10 pages). Ordering information is given on any current masthead page.

Contribution from the Department of Chemistry and Ames Laboratory-USDOE, Iowa State University, Ames, Iowa 5001 1

Coordination Chemistry of Bis( 6-camphorquinone dioximato)nickel(II) and -palladium(II). Reactions and Structural Studies of Some M3Ag3 Cluster Complexes of Camphorquinone Dioxime MAN SHEUNG MA, ROBERT J. ANGELICI,* DOUGLAS POWELL, and ROBERT A. JACOBSON*

Received March 17, I980 Reactions of AgN03 with Ni(6-HCQD)2or P ~ ( I ~ - H C Q Dwhere ) ~ , 6-HCQD- is 6-camphorquinone dioximato, yielded the Ni-Ag, and [Pd(6-HCQD)2Ag]3.2CHC13, Pd-Ag, hexanuclear metal cluster complexes [Ni(6-HCQD),Agl3.2.5CHCl3, respectively. X-ray crystallographic studies performed on both complexes showed them to belong to space group P212121, The unit cell dimensions of Ni-Ag are a = 15.990 (5) A, b = 38.44 (1) A, c = 13.437 (5) A, V = 8260.97 A3, and Z = 4 while those of Pd-Ag are a = 16.110 (6), b = 38.92 (l), c = 13.393 (3) A, V = 8395.55 A', and Z = 4. Block-diagonal least-squares refinement of 3021 observed reflections for Ni-Ag and 61 12 for Pd-Ag converged to RF = 10.7 and 11.4 ( R , = 12.7 and 15.0) for the Ni-Ag and Pd-Ag structures, respectively. Their structures indicate that each hexanuclear molecule consists of three individual M(G-HCQD),- units which act as multidentate ligands coordinating to a linear chain of three silver atoms. The coordination geometry around each M ion in the M(6-HCQD)Y units is square planar, and the 6-HCQD- ligands are coordinated to M via N and 0 atoms. The Ag in the center of the molecule is coordinated to six 0 atoms with average Ag-0 distances of 2.49 (3) and 2.45 (2) A for Ni-Ag and Pd-Ag, respectively. The two silver atoms at the ends of the chain are each coordinated to three nitrogen atoms from the M(G-HCQD),- units with average Ag-N distances of 2.20 (4) and 2.27 (3) A, respectively. The Ag-Ag distances, 3.059 (5) and 3.052 (5) A in Ni-Ag and 3.173 (3) and 3.179 (3) A in Pd-Ag, are somewhat longer than those (2.89 A) in Ag metal and indicate that there are Ag-Ag interactions along the linear chains. The bis(pyridine) adduct of Ni(G-HCQD), was also prepared. A proposed structure for this complex is based on the similarity of its IR spectrum to those of the Ni-Ag and Pd-Ag clusters.

Introduction Our earlier work,1.2 as well as that of Nakamura e t al.,3 showed that a- and 8-camphorquinone dioximes (H2CQD) form square-planar Ni(I1) and Pd(I1) complexes in which the ligands chelate via nitrogen and oxygen donor atoms. The structurek of Ni(G-HCQD), is shown in Figure 1. In t h e present paper, we report the reactions of Ni(6H C Q D ) 2 and Pd(G-HCQD), with A g N 0 3 to form hexanuclear clusters of t h e composition [M(8-HCQD),Ag13, where M is Ni(I1) or Pd(I1). Results of crystallographic studies on both of these complexes are described. It has also been found that Ni(G-HCQD), reacts with pyridine to give an adduct whose proposed structure is related to that of the clusters.

Experimental Section Spectral Data. Proton NMR spectra were obtained by using a Varian HA-100 spectrometer with Me4Si as the internal reference and CDClt as the solvent. The I3C NMR spectra were recorded on (1) Ma, M. S.;Angelici, R. J.; Powell, D.; Jacobson, R. A. 1.Am. Chem. SOC.1978, 100, 7068. (2) Ma, M. S.; Angelici, R. J. Inorg. Chem. 1980, 19, 363. (3) Nakamura, A.; Konishi, A.; Otsuka, S. J . Chem. SOC.,Dalton Trans. 1979, 488.

a JEOL FX-90Q I3C NMR/'H spectrometer. Infrared spectra were obtained on KBr pellets with a Beckman IR-4250 (4000-200 cm-I) spectrophotometer. Electronic spectra were recorded on a JASCOORD/UV-5 or Cary 14 spectrophotometer. Starting Materials. The complexes Pd(G-HCQD),, Ni(G-HCQD),, and N~(cI-HCQD)~were prepared according to published procedures? The Pd(PhCN)2C12 was prepared by the method of Doyle et al.4 Preparation of [Ni(6-HCQD)2Ag]3-2.5CHC13. To 3 mL of a CHC13 solution containing 0.05 g (0.1 1 mmol) of Ni(&HCQD), was added approximately 5 mL of 0.05 M aqueous AgN0, solution. The two solution layers were mixed together by adding MeOH (1 5 mL) until a homogeneous solution was obtained. The resulting green solution was allowed to evaporate overnight at room temperature. After 24 h green needlelike crystals were obtained; yield 90%. IR (KBr): v(C=N) 1615, 1560 cm-l. 'H NMR (CDC13): 6 3.20 (d), C4-H; 1.12 (s), 0.86 (s), 0.78 (s), Me. I3C NMR (CDC13) (ppm): 153.76, 153.49, 147.42, 147.31, oxime C; 20.0, 17.35, 11.99, Me. UV-vis maxima (CHCI,): 620nm (53 cm-l M-I), 402 (1.2 X lo3), 305 (1.5 X lo4). Anal. Calcd for [Ni(CmH29N404)Ag]j.2.5CHC13: C, 38.22; H, 4.60; N, 8.56; C1, 13.54; Ag, 16.48. Found: C, 37.94; H, 4.70; N, 8.45; C1, 13.60; Ag, 17.13. Preparation of [Pd(6-HCQD)2Ag]3-2CHC13. Yellow crystals of [Pd(6-HCQD)2Ag]3.2CHC13were prepared by using the same pro(4) Doyle, J . R.; Slade, P. E.; Jonassen, H. B. Inorg. Synth. 1960, 6, 218.

0020-1669/80/1319-3121$01.00/00 1980 American Chemical Society

3122 Inorganic Chemistry, Vol. 19, No. 10, 1980

Ma et al.

reflections for Pd-Ag) within a 20 sphere of 40" in the case of Ni-Ag and 60" in the case of Pd-Ag in the hkl octant were measured using an w-step-scan technique. As a general check on electronic and crystal stability, the intensities of three standard reflections were measured every 75 reflections. These standard reflections were not observed to vary significantly throughout the data collection period (-6 days) for the Pd-Ag complex but Figure 1. Structure of Ni(G-HCQD),. indicated considerable decay for the Ni-Ag complex in the last 1025 reflections. The decay as measured from the standard reflections was cedure as for [Ni(G-HCQD)2Ag]3.2.5CHC13 substituting Pd(6found to fit a quadratic polynomial by the least-squares method: y ( x ) HCQD), for Ni(G-HCQD),; yield 80%. IR (KBr): v(C=N) 1605, = 5979 (-0.2615)~+ (-0.0007267)~~.Subsequently all reflections 1550 cm-'. 'H N M R (CDCI,): 6 3.31 (d), C4-H; 1.24 (s), 0.90 (s), after the first 3375 in the Ni-Ag complex were divided by y(x)/y(O) 0.78 (s), Me. I3C N M R (CDCI3) (ppm): 153.70, 142.49, oxime C; = 1.0 (-0.4374 X 10-5)x + (-1.216 X 10-')x2 to account for the 20.05, 17.40, 12.58, Me. UV-vis maxima (CHCI,): 362 nm (1.8 decay correction. X lo3cm-' My'). Anal. Calcd for [Pd(C20HzsN404)Ag]3~2CHC13: Examination of data revealed systematic absences of hOO, OkO, 001 C, 36.37; H, 4.39; N , 8.21; C1, 10.39; Ag, 15.81. Found: C, 36.27; reflections for h = 2n + 1, k = 2n + 1 , 1 = 2n + 1 in the Ni-Ag and H , 4.54; N , 8.04; CI, 7.22; Ag, 15.48. Pd-Ag structures, thus uniquely defining the space group P212121 Preparation of N~(CY-HCQD)~A~~O.~A~NO~.H~O. This complex was prepared in the same manner as [Ni(6-HCQD)2Ag]3,2.5CHC13 in both cases. The intensity data were corrected for Lorentz and polarization effects. An absorption correction was applied to the data substituting Ni(a-HCQD), for Ni(G-HCQD),; yield 90%. IR (KBr): of the Pd-Ag complex. However, no absorption correction was applied v(C=N) 1615, 1550 cm-I. UV-vis maxima (CHCI,): 402,302 nm. to the Ni-Ag data because the crystal diffracted only out to 40' in Anal. Calcd for Ni(CZOH29N404)Ag0.5AgN03.H20: C, 36.44; H, 28 and because the transmission factors were in the range 0.80 f 0.09. 4.75; N , 9.57; Ag, 24.55. Found, C, 36.64; H, 4.47; N, 9.37; Ag, The estimated error in each intensity was calculated by u? = CT 24.62. KtCB + (O.03CT), + (O.O3CB)', where CT,K,, and CBrepresent the Preparation of Pd(a-HCQD)2Ag0.5AgN03. To 20 mL of MeOH total count, a counting time factor, and background count, respectively, containing 0.32 mmol of a-H2CQDwas added an equivalent amount and the factor 0.03 represents an estimate of nonstatistical errors. of Et3N (0.32 mmol), followed by 0.16 mmol of Pd(PhCN),CI2. After The estimated deviations in the structure factors were calculated by being stirred at 50' C for 2-3 h, the yellow solution was filtered and the finite-difference m e t h ~ d . ~Since only one octant of data was cooled to room temperature. Then aqueous AgNO, (0.05 M) was collected in each case, no averaging of data was required. While 3021 added until no further precipitation of AgCl was observed. The reflections with 1, > 3u1 from Ni-Ag were retained for structural solution was then filtered into a flask containing 10 mL of CHCI,. solution and refinement, 61 12 reflections from Pd-Ag were retained. When the solution was allowed to stand overnight, the product PdSolution and Refinement of the Structures. The positions of the (a-HCQD)2Ag0.5AgN03crystallized out as pale yellow microcrystals, heavy atoms in the asymmetric unit were obtained from an analysis yield 8Wh. IR (KBr): v(C=N) 1600, 1550 cm-'. UV-vis maximum of a standard sharpened three-dimensional Patterson map.' The (CHC13): 362 nm. Anal. Calcd for Pd(C20H29N404)Ag0.5AgN03: remaining nonhydrogen atoms were found by successive structure C, 34.87; H, 4.25; N , 9.14; Ag, 23.49. Found: C, 34.98; H, 4.21; factor and electron density map calculations.* A block-matrix N , 9.42; Ag, 22.59. least-squares procedure' was used to refine the atomic positional Preparation of [Ni(S-HCQD)2(py)21.CHC13. This complex was parameters with anisotropic thermal parameters for the metal atoms prepared by dissolving 0.05 g (0.11 mmol) of Ni(G-HCQD), in 20 and isotropic thermal parameters for the remaining nonhydrogen atoms mL of H20/MeOH/CHC13 (1:3:1) to which 1 mL of pyridine (py) to conventional discrepancy factors of R = CIIF,I - IFcll/CIFoll = was added. After the solution was allowed to stand at room tem10.7 and 11.4 and weighted R values of 12.7 and 15.0 for the Ni-Ag perature for several days, green crystals of [Ni(6-HCQD)z(py)z]. and Pd-Ag structures, respectively, by using weights of l/aF2. There CHCI, were obtained; yield 80%. IR (KBr): v(C=N) 1610, 1558 were three possible solvent sites in both structures. The Pd-Ag cm-'. UV-vis maxima (CHCI,): 614 nm (58 cm-I M-I), 296 (1.4 structure indicated that all three sites had disordered CHCI, molecules. X lo4). A (CH3CN): 0.534 cm2 Q-' M-' at 25" C. Anal. Calcd Although two of the solvent sites in the Ni-Ag structure also exhibited for Ni(C20H29N404)(C5H5N)2-CHC13: C, 5 1.23; H, 5.70; N, 11.57. peaks corresponding to disordered CHC1, molecules, the third site Found: C, 51.26; H , 6.02; N, 11.71. contained much less electron density. Both structures contained less Crystal Data. [Ni(6-HCQD)2Ag]3.2.5CHC13: mol wt 1832.40, solvent than was indicated by the elemental analyses. This is believed orthorhombic P2'2,2', a = 15.990 ( 5 ) A, b = 38.44 (1) A, c = 13.437 to be due to some loss of solvent during data collection. The decay ( 5 ) A, V = 8260.97 A3, p c = 1.474 g/cm3, 2 = 4, p = 15.32 cm-' observed in the standard reflections, especially evident for the Ni-Ag mol wt 1945.62, orthofor Mo Ka. [Pd(S-HCQD)2Ag]3.2CHC13: crystal, would be consistent with ready solvent loss. Thermal and rhombicP2,2,2,, a = 16.110 (6) A, b = 38.92 (1) A, c = 13.393 (3) occupancy factors were estimated from successive electron density A, V = 8395.55 A3, p c = 1.540 g/cm3, Z = 4, p = 14.47 cm-' for difference maps. In both structures, final electron density difference Mo Ka. The [Ni(b-HCQD),Ag],.2SCHCl3 cluster will be referred maps revealed no peaks larger than 1.0 e/A3. Hydrogen positions to as Ni-Ag, while [Pd(G-HCQD),Ag],.ZCHCI, will be designated in the terminal methyl groups and in the bicyclic rings were calculated Pd-Ag in the discussion below. by using a 1.07 A C-H bond distance and tetrahedral H-C-H angles A 0.36 X 0.19 X 0.16 mm single crystal of Ni-Ag and a 0.30 X in both Ni-Ag and Pd-Ag. They were included but not refined during 0.08 X 0.10 mm crystal of Pd-Ag were used in the collection of X-ray the last least-squares refinement cycles. The scattering factors for intensity data. In each case, 12-1 5 independent reflections taken from nonhydrogen atoms were those of Hanson et al.," modified by the four preliminary w-oscillation photographs at various x and 4 settings real and imaginary parts of anomalous dispersion." Scattering factors were input to the automatic indexing program ALICE.' The resulting for Ni(II), Pd(II), and Ag(1) were those of Thomas and Umeda.'* reduced cell and reduced cell scalars indicated P212121(orthorhombic) symmetry in both cases. This was confirmed by inspection of axial w-oscillation photographs which showed mmm symmetry in both Lawton, S. L.; Jacobson, R. A. Inorg. Chem. 1968, 7 , 2124. Ni-Ag and Pd-Ag. The final lattice constants were obtained by using Hubbard, C. A,; Quicksall, C. W.; Jacobson, R. A. "The Fast Fourier least-squares refinement based on the precise A28 measurement of Algorithm and the Programs ALFF, ALFFDP, ALFFPROJ, ALFFT 13 independent reflections with 1281 > 20' for Ni-Ag and 15 indeand FRIEDEL", US.Atomic Energy Commission Report IS-2625; pendent reflections with 1281 > 30" for Pd-Ag. Iowa State University and Institute for Atomic Research: Ames, Iowa, Collection and Reduction of X-ray Intensity Data. The data were 1971. collected at 25 "C with use of graphite-monochromated Mo K a Lapp, R. L.; Jacobson, R. A. "ALL, a Generalized Crystallographic Least-Squares Program", U.S. DOE Report IS-4708; Ames radiation on an automated four-circle diffractometer designed and Laboratory-DOE and Iowa State University: Ames, Iowa, 1979. built at the Ames Laboratory and previously described by Rohrbaugh Hanson, H . P.; Herman, F.; Lea, J. D.; Skillman, S. Acta Crystallogr. and Jacobsoa6 All data (4412 reflections for Ni-Ag and 6524 1960, 17, 1040.

+ +

+

( 5 ) Jacobson, R. A. J . Appl. Crystallogr. 1976, 9, 115. (6) Rohrbaugh, W. J.; Jacobson, R. J. I m r g . Chem. 1974, 13, 2535.

Templeton, D. H . "International Tables for X-ray Crystallography"; Kynoch Press: Birmingham, England, 1962; Vol. 111, Table 3.3.2C. pp 21 5-216. Thomas, L. H.; Umeda, K. J . Chem. Phys. 1957, 26, 293.

M3Ag3Cluster Complexes of Camphorquinone Dioxime

Inorganic Chemistry, Vol. 19, No. 10, 1980 3123

Figure 2. Stereoscopic view of the unit cell of [Ni(6-HCQD)2Ag]3.2.5CHC13 with the a axis vertical and the b axis horizontal.

Hydrogen scattering factors were those of Stewart et al.I3 Final positional and thermal parameters for Ni-Ag and Pd-Ag are listed in Tables I and 11, respectively. Results and Discussion Description of the Structure [Ni(6-HCQD)2Ag]3.2.5CHC13, Ni-Ag. The unit cell (Figure 2) of Ni-Ag consists of four hexanuclear molecules with CHCl, molecules occupying interstitial sites. Each hexanuclear molecule (Figure 3) in turn consists of three individual Ni(6-HCQD)y ligands coordinated to a linear chain of three silver atoms. The 6-HCQD- ligands form two six-membered chelate rings with each of the three Ni(I1) atoms. The observed coordination of the ligands to Ni via N and 0 rather than two N atoms was established previously in Ni(G-HCQD)21and probably is caused by the bicyclic nature of the ligand which increases the size of the C-C-N angles and thus favors six-membered chelate ring formation. There are two types of Ag atoms in the cluster. Coordinated to the center Ag are six oxygen atoms, while there are three nitrogen atoms coordinated to each of the terminal silver atoms. Several interesting features of the structure are discussed below. Coordination around Ni. While the crystal structure' of Ni(G-HCQD)* was found to have trans-N202square-planar coordination around Ni (Figure l), the 6-HCQD- ligands in Ni-Ag coordinate to the Ni with a cis-N202geometry (Figure Figure 3. Molecular structure of [Ni(G-HCQD),Ag], with 50% 3). Thus, the addition of Ag' to Ni(G-HCQD), has caused probability ellipsoids for heavy atoms but 10% for light atoms. For one ligand in N ~ ( C ~ - H C QtoDrotate ) ~ such that the structure clarity only the C atoms of the Ni2 unit are labeled but the adopted numbering scheme is also applied to the other two units. around the Ni changes from trans-N202to cis-N202. The important bond distances and bond angles of the three Ni(6-HCQD)2- units in Ni-Ag are summarized in Tables I11 04-Ni-01 angles (75.9 ( l ) , 77.2 ( l ) , and 80.5 (1)') so that and IV. The avera e Ni-N distance of 1.86 (4) 8, is comthey are consistently smaller than the other angles, O4-Ni-N3, parable to 1.855 (3) reported in the Ni(6-HCQD) complex.' N3-Ni-N2, and N2-Ni-01, which are all greater than 90' However, the average Ni-0 distance of 1.87 (3) 8, is longer in the three nickel anion ligands. The distances of the Ni than the 1.830 (3) A observed in Ni(G-HCQD),. This atoms from the least-squares planes defined by Ni-Ol-04lengthening is presumably due to coordination of the Ag(1) N2-N3 are small, being only 0.04, 0.006, and 0.01 A for the to these 0 atoms. Also such coordination seems to affect the three units. The average C-C (1.53 A), C=N (1.28 A), and N-0 (1.38 A) distances of the ligands correspond well with those observed in the structures of Ni(6-HCQD)21 and y(13) Stewart, R. F.; Davidson, E. R.: Simpson, W. T. J . Chem. Phys. 1965, H2CQD.14 42, 3175.

R

~~

3124 Inorganic Chemistry, Vol. 19, No. 10, 1980

Ma et al.

Table I. Final Atomic Parameters of the Ni-Ag Structurea

X

(a) Final Positional Parameters and Isotropic Thermal Parameters ( B ) of the Light Atoms Y 2 B, A’ X Y

0.2093 (2) 0.1705 (1) -0.0952 (3) Ag 1 0.1124 (1) -0.1801 (3) 0.3188 (2) Ag2 0.0530 (1) -0.2658 (3) 0.4230 (2) Ag 3 Ni 1 0.1239 (2) 0.0159 (5) 0.4713 (4) Ni2 0.0568 (2) -0.1905 (5) 0.1326 (4) 0.1704 (2) -0.3759 (4) Ni 3 0.3937 (4) 0.4422 (18) 101 0.0951 (7) -0.0944 (23) 102 0.6331 (19) 0.1170 (8) 0.1003 (25) 103 0.5524 (2 1) 0.1625 (9) 0.1716 (26) 0.3700 (19) 104 0.1418 (8) -0.0279 (23) 1N1 0.4795 (23) 0.0620 (10) -0.1228 (29) 1N2 0.5747 (25) 0.1038 (9) 0.0399 (29) 1N3 0.4795 (23) 0.1588 (9) 0.1187 (29) 1N4 0.3152 (22) 0.1676 (9) 0.0088 (26) 1c10 0.0005 (15) -0.1742 (46) 0.5666 (37) lCll 0.0218 (11) -0.0934 (34) 0.5987 (27) 1c12 0.5451 (29) 0.0515 (13) -0.0769 (36) 1C13 0.5972 (27) 0.0710 (11) 0.0084 (32) 1C14 0.6786 (33) 0.0491 (14) 0.0180 (40) 1C15 0.6392 (35) 0.0198 (14) 0.0848 (44) 1C16 0.5909 (32) 0.0020 (13) 0.0047 (39) 1C17 0.0359 (15) -0.0830 (48) 0.6834 (38) 1C18 0.7012 (34) 0.0579 (14) -0.1699 (43) 1c19 0.7529 (33) 0.0062 (13) -0.0904 (40) 0.1959 (34) 1c20 0.2097 (14) 0.1276 (42) 1c21 0.2937 (33) 0.2093 (13) 0.1471 (39) 0.3422 (28) 1c22 0.1816 (12) 0.0903 (36) 1C23 0.4188 (27) 0.1793 (10) 0.1414 (30) 1C24 0.4175 (31) 0.2034 (12) 0.2243 (36) 1C25 0.4248 (35) 0.2382 (14) 0.1791 (43) 0.3418 (29) 1C26 0.2432 (12) 0.1119 (37) 1C27 0.3221 (28) 0.2037 (12) 0.2568 (34) 1C28 0.2953 (32) 0.1685 (14) 0.2991 (39) 1C29 0.2920 (42) 0.2307 (17) 0.3259 (53) 0.2441 (17) 0.0572 (7) -0.2207 (20) 201 0.0006 (10) -0.2628 (30) 0.0350 (24) 202 2 0 3 -0.0342 (22) 0.0353 (9) -0.1395 (27) 0.1677 (16) 0.1016 (7) -0.1442 (20) 204 2N1 0.0339 (9) -0.2699 (28) 0.2948 (22) 0.1 167 (20) 2N2 0.0143 (8) -0.2601 (25) 2N3 0.0614 (10) -0.1374 (28) 0.0271 (23) 0.1269 (9) -0.1081 (29) 0.1224 (23) 2N4 2c10 0.3948 (33) -0.0268 (13) -0.3559 (39) 0.2986 (31) -0.0229 (12) -0.3757 (38) 2Cll 2c12 0.0089 (11) -0.3081 (36) 0.2535 (28) 2C13 0.1661 (28) -0.0011 (12) -0.3125 (38) 2C14 0.1602 (30) -0.0351 (12) -0.3694 (37) 0.1790 (34) -0.0217 (14) -0.4662 (42) 2C15 2C16 0.2642 (39) -0.0143 (15) -0.4752 (48) 0.2388 (37) -0.0522 (16) -0.3372 (46) 2C17 0.2574 (42) -0.0868 (16) -0.4012 (53) 2C18 0.2474 (34) -0.0628 (14) -0.2316 (42) 2C19 2c20 0.1843 (1 3) -0.0426 (41) 0.0064 (33)

5.0 (7) 6.2 (8) 7.4 (9) 5.3 (7) 5.4 (9) 5.6 (9) 5.0 (9) 5.2 (8) 7.9 (16) 5.0 (10) 4.9 (12) 4.6 (10) 6.3 (13) 7.7 (15) 6.4 (13) 7.5 (16) 7.3 (14) 6.9 (13) 6.9 (14) 6.3 (13) 5.9 (11) 4.3 (10) 5.2 (12) 8.4 (14) 5.5 (12) 4.8 (11) 6.4 (13) 9.4 (19) 4.2 (6) 7.5 (10) 8.4 (10) 4.5 (7) 5.2 (9) 5.5 (9) 3.9 (8) 4.9 (9) 6.3 (13) 6.0 (12) 4.5 (11) 5.0 (11) 5.3 (12) 7.6 (14) 8.7 (17) 8.4 (16) 9.2 (18) 7.4 (15) 6.4 (14)

2c21 2c22 2C23 2C24 2C25 2C26 2C27 2C28 2C29 301 302 303 304 3N1 3N2 3N3 3N4 3C10 3Cll 3C12 3C13 3C14 3C15 3C16 3C17 3C18 3C19 3C20 3C21 3C22 3C23 3C24 3C25 3C26 3C27 3C28 3C29 lCllb (0.4)c 1C12 (0.4) 1C13 (0.4) 1C14 (0.25) 1C15 (0.25) 1C16 (0.25) lCSl (0.4) 1CS2 (0.25) 2Cll (0.4) 2Cl2 (0.4) 2C13 (0.4) 2C14 (0.25) 2C15 (0.25) 2C16 (0.25) 2CS2 (0.25) 1 0 s (0.55)

(b) Anisotropic Thermal Parameters Agl Ag2 Ag3

396 (18) 400 (16) 411 (17)

69 (3) 58 (3) 67 (3)

805 (29) 718 (26) 793 (29)

3 (6) 0 (6) 0 (7)

-48 (20) 24(19) -41 (21)

18 (9) 32 (8) 24 (8)

(X

-0.0207 (34) 0.0456 (30) -0.0004 (26) -0.0959 (29) -0.0732 (38) -0.0207 (35) -0.1014 (34) -0.1003 (32) -0.1834 (37) 0.4007 (18) 0.5043 (19) 0.4149 (22) 0.3154 (18) 0.4524 (22) 0.4751 (20) 0.3720 (19) 0.2671 (23) 0.5395 (34) 0.5639 (28) 0.4991 (28) 0.5 107 (36) 0.5769 (30) 0.6617 (31) 0.6442 (33) 0.5593 (36) 0.4772 (33) 0.6206 (32) 0.1713 (38) 0.2108 (26) 0.2678 (27) 0.3136 (30) 0.2921 (30) 0.2035 (41) 0.1468 (30) 0.2739 (33) 0.3526 (36) 0.2323 (33) 0.5515 (27) 0.6120 (22) 0.58 10 (24) 0.6242 (31) 0.5 138 (32) 0.5787 (34) 0.5533 (73) 0.5731 (132) 0.25 10 (21) 0.1438 (21) 0.1095 (21) 0.0774 (34) 0.2171 (37) 0.1878 (36) 0.1883 (121) 0.5187 (37)

0.1459 (14) 0.1213 (13) 0.0882 (11) 0.0944 (1 1) 0.0948 (14) 0.1328 (14) 0.1357 (13) 0.1389 (12) 0.1483 (15) 0.1247 (7) 0.1934 (8) 0.2343 (8) 0.1706 (8) 0.0974 (9) 0.1645 (8) 0.2162 (8) 0.1947 (10) 0.0397 (14) 0.0762 (1 1) 0.1057 (12) 0.1379 (14) 0.1313 (11) 0.1254 (13) 0.0913 (14) 0.095 3 (14) 0.0913 (13) 0.0758 (13) 0.2504 (16) 0.2565 (10) 0.2237 (11) 0.2354 (12) 0.2748 (12) 0.2728 (16) 0.2599 (12) 0.2838 (13) 0.2812 (15) 0.3215 (14) 0.2176 (12) 0.1534 (9) 0.2004 (9) 0.1758 (13) 0.2174 (13) 0.2081 (14) 0.1934 (30) 0.2042 (55) 0.1022 (9) 0.1527 (9) 0.0815 (9) 0.1022 (13) 0.0922 (15) 0.1528 (14) 0.1171 (51) 0.3270 (16)

Z

B, A2

-0.0266 (41) -0.0818 (38) -0.0871 (33) -0.0466 (35) 0.0663 (45) 0.0836 (43) -0.0798 (41) -0.1850 (39) -0.0230 (45) -0.3379 (21) -0.5306 (24) -0.4723 (25) -0.2693 (22) -0.3632 (28) -0.4718 (24) -0.4004 (24) -0.2356 (28) -0.4584 (42) -0.4849 (33) -0.4437 (36) -0.4916 (43) -0.5723 (34) -0.5082 (38) -0.4515 (41) -0.5972 (46) -0.6463 (40) -0.6605 (39) -0.1438 (45) -0.2434 (32) -0.2734 (34) -0.3633 (36) -0.3695 (37) -0.4115 (52) -0.3211 (38) -0.2640 (41) -0,1931 (45) -0.2598 (42) -0.2676 (34) -0.2148 (26) -0.0690 (28) -0.1071 (40) -0.0980 (41) -0.2846 (40) -0.1930 (95) -0.2743 (167) -0.4902 (26) -0.4040 (26) -0.4340 (26) -0.3785 (41) -0.4421 (45) -0.4734 (43) -0.4164 (152) -0.3466 (44)

6.8 (14) 5.7 (12) 4.1 (10) 5.0 (1 1) 8.5 (16) 6.8 (14) 6.1 (14) 6.2 (13) 8.5 (16) 4.8 (7) 5.7 (8) 6.8 (8) 5.2 (7) 5.2 (9) 3.7 (8) 3.2 (7) 4.7 (9) 6.7 (14) 4.5 (10) 4.9 (11) 6.5 (15) 5.2 (1 1) 6.1 (13) 5.9 (14) 7.7 (15) 7.4 (14) 6.4 (13) 9.4 (17) 3.9 (10) 4.9 (1 1) 5.6 (12) 5.6 (12) 9.8 (18) 5.9 (12) 6.6 (14) 7.8 (15) 7.4 (14) 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0

lo5)of the Heavy Atomsd

Nil 390 (30) Ni2 404 (30) Ni3 429 (31)

58 (5) 709 (47) 55 (5) 676 (45) 57 (5) 633 (44)

-6 (11) -7 (10) 13 (11)

8 (34) -2 (14) -44 (33) 18 (14) -55 (31) -2 (14)

In all tables, estimated standard deviations are given in parentheses. Only 1.3 CHC1, rather than 2.5 CHC!, as indicated by elemental analyses was observed on an electron density difference map. Multiplier used. The Pij are defined by T = exp[-(h2p,, + k2p,, + 1 2 p , , + 2hkp12 + 2hlP13 2klP23)l.

Since intramolecular H bonding is of interest in almost all metal dioxime complexes, it is worthwhile to mention the 0 2 - 0 3 distances (2.38 (5), 2.40 (5), and 2.27 (4) A) for the three anion They are to the 2.40 8, reported for the dimethylglyoximato complex Ni(HDMG)215and other related oxime metal complexes.16 (14) Ma, M. S.; Angelici, R. J.; Jacobson, R. A,, unpublished work.

Since the 0 2 - 0 3 bond distances are not equal in the three Ni(G-HCQD)2- ligands, they appear to be affected by crys(15) (a) Godycki, L. E.; Rundle, R. E. Acta Crystallogr. 1953, 6,487. (b) Williams, D. E.; Wohlauer, G.; Rundle, R. E. J . Am. Chem. Soc. 1959, 81, 755. (16) (a) Hussain, M. S.; Salinas, B. E. V.; Schlemper, E. 0. Acta Crystallogr., Sect. 5 1979,535, 628. (b) Schlernper, E. 0.Inorg. Chern. 1968, 7, 1130. (c) Bowers, R. H.; Banks, C. V.; Jacobson, R. A. Acta Crystallogr., Sect. 5 1972, 828, 2318.

Inorganic Chemistry, Vol. 19, No. 10, 1980 3125

M3Ag3Cluster Complexes of Camphorquinone Dioxime Table 11. Final Atomic Parameters of the Pd-Ag Structure

(a) Final Positional Parameters and Isotropic Thermal Parameters (B) of the Light Atoms X

An1 Ai2 Ag3 Pdl Pd2 Pd3 101 102 103 104 1N1 1N2 1N3 1N4 lCl0 IC11 1C12 1C13 1C14 1C15 1C16 1C17 1C18 1C19 1C20 1C21 1C22 1C23 1C24 1C25 1C26 1C27 1C28 1C29 201 202 203 204 2N1 2N2 2N3 2N4 2C10 2C11 2C12 2C13 2C14 2C15 2C16 2C17 2C18 2C19

0.29459 (13) 0.18500 (12) 0.07899 (13) 0.02627 (13) 0.37097 (12) 0.10885 (13) 0.0538 (11) -0.1388 (12) -0.0548 (13) 0.1379 (11) 0.0174 (14) -0.0812 (15) 0.0151 (15) 0.1784 (13) -0.0710 (24) -0.1012 (22) -0.0516 (17) -0.0987 (17) -0.1820 (19) -0.1500 (18) -0.1018 (24) -0.1916 (17) -0.2584 (28) -0.2074 (21) 0.2931 (21) 0.1966 (19) 0.1513 (15) 0.0704 (17) 0.0667 (19) 0.0635 (25) 0.1491 (23) 0.1582 (20) 0.1851 (28) 0.1890 (25) 0.2493 (11) 0.4695 (14) 0.5397 (14) 0.3324 (11) 0.2095 (14) 0.3946 (14) 0.4820 (14) 0.3833 (14) 0.1141 (20) 0.2009 (22) 0.2487 (18) 0.3384 (17) 0.3457 (19) 0.3389 (23) 0.2388 (26) 0.2665 (19) 0.2593 (21) 0.2433 (27)

Y

z

0.32877 (5) 0.38870 (5) 0.44983 (5) 0.37629 (5) 0.44287 (4) 0.33064 (5) 0.4079 (5) 0.3859 (5) 0.3389 (5) 0.3573 (4) 0.4387 (6) 0.4000 (6) 0.3414 (6) 0.3339 (5) 0.5017 (10) 0.4808 (9) 0.4463 (7) 0.4291 (7) 0.4494 (8) 0.4783 (7) 0.4983 (10) 0.4646 (7) 0.4938 (10) 0.4408 (8) 0.2897 (8) 0.2900 (8) 0.3186 (6) 0.3194 (6) 0.2956 (7) 0.2599 (10) 0.2557 (9) 0.2966 (8) 0.2655 (11) 0.3314 (10) 0.4438 (4) 0.5007 (6) 0.4623 (5) 0.3972 (4) 0.4679 (5) 0.4872 (5) 0.4380 (5) 0.3734 (5) 0.5273 (8) 0.5229 (9) 0.4946 (7) 0.5032 (7) 0.5374 (7) 0.5248 (9) 0.5142 (9) 0.5540 (7) 0.5650 (8) 0.5889 (10)

0.40075 (20) 0.30904 (19) 0.21672 (20) 0.49885 (20) 0.29997 (19) 0.11501 (19) 0.3827 (17) 0.5920 (17) 0.6592 (18) 0.4567 (15) 0.3597 (20) 0.5254 (20) 0.6090 (21) 0.5103 (17) 0.3055 (34) 0.3946 (31) 0.4056 (24) 0.4849 (24) 0.4961 (27) 0.5686 (26) 0.4895 (34) 0.3893 (24) 0.3913 (35) 0.3138 (30) 0.6230 (28) 0.6360 (27) 0.5801 (21) 0.6344 (22) 0.7120 (26) 0.6574 (33) 0.6086 (33) 0.7466 (28) 0.8196 (40) 0.7868 (35) 0.2654 (14) 0.2286 (19) 0.3444 (19) 0.3522 (15) 0.2114 (20) 0.2307 (19) 0.3530 (20) 0.3950 (19) 0.1258 (28) 0.1225 (31) 0-1793 (22) 0.1835 (24) 0.1285 (27) 0.0164 (33) 0.0145 (36) 0.1484 (26) 0.2586 (29) 0.0930 (40)

B, A'

4.5 (4) 5.7 (4) 6.1 (5) 4.6 (4) 4.4 (5) 5.2 (5) 4.8 (5) 3.8 (4) 7.1 (9) 6.9 (8) 4.8 (6) 5.3 (6) 5.2 (7) 5.9 (6) 6.0 (9) 5.1 (6) 7.9 (9) 5.9 (8) 6.2 (7) 5.5 (7) 3.8 (5) 3.7 (6) 5.6 (7) 7.9 (9) 6.6 (1 1) 6.8 (7) 9.1 (10) 8.6 (10) 4.2 (3) 6.5 (5) 6.4 (5) 4.3 (4) 4.4 (5) 5.2 (5) 4.6 (5) 4.6 (5) 6.3 (7) 7.6 (8) 3.3 (6) 4.4 (6) 5.1 (7) 9.1 (9) 8.4 (11) 5.0 (7) 8.0 (8) 9.2 (11)

2c20 2c2 1 2c22 2C2 3 2C24 2C25 2C26 2C27 2C28 2C29 301 302 303 30 4 3N1 3N2 3N3 3N4 3C10 3Cll 3C12 3C13 3C14 3C15 3C16 3C17 3C18 3C19 3C20 3C2 1 3C22 3C23 3C24 3C25 3C26 3C27 3C28 3C29 C1 (0.5)' C2 (0.5) C3 (0.5) lCll (0.3) 1C12 (0.3) 1C13 (0.3) 1C14 (0.2) 1C15 (0.2) 1C16 (0.2) 2Cll (0.3) 2C12 (0.3) 2C13 (0.3) 3Cll (0.3) 3C12 (0.3) 3C13 (0.3)

X

Y

Z

B, A2

0.4863 (20) 0.5108 (20) 0.4556 (18) 0.5007 (16) 0.5904 (22) 0.5799 (26) 0.5201 (23) 0.5891 (17) 0.6009 (24) 0.6710 (21) 0.1044 (11) -0.0055 (12) 0.0807 (13) 0.1923 (12) 0.0535 (15) 0.0226 (14) 0.1271 (14) 0.2423 (15) -0.0294 (21) -0.0523 (19) 0.0084 (17) -0.0131 (18) -0.0791 (19) -0.1574 (21) -0.1415 (24) -0.0594 (19) -0.1196 (22) 0.0282 (24) 0.3304 (23) 0.2868 (20) 0.2355 (15) 0.1806 (20) 0.2029 (21) 0.2923 (24) 0.3535 (28) 0.2208 (17) 0.1461 (22) 0.2689 (26) 0.4331 (58) 0.0674 (101) 0.3183 (99) 0.3849 (26) 0.4417 (26) 0.4131 (27) 0.4698 (39) 0.4110 (39) 0.3655 (39) 0.1124 (26) 0.1146 (26) 0.1121 (25) 0.3716 (27) 0.3964 (26) 0.2984 (27)

0.3178 (8) 0.3544 (7) 0.3788 (7) 0.4105 (6) 0.4043 (9) 0.4074 (11) 0.3698 (9) 0.3652 (7) 0.3537 (9) 0.3482 (8) 0.3797 (4) 0.3075 (4) 0.2640 (5) 0.3334 (5) 0.4037 (6) 0.3360 (5) 0.2803 (5) 0.3059 (6) 0.4603 (8) 0.4229 (8) 0.3964 (7) 0.3631 (7) 0.3680 (7) 0.3756 (8) 0.4096 (10) 0.4078 (8) 0.4251 (9) 0.4066 (9) 0.2486 (9) 0.2450 (8) 0.2751 (6) 0.2640 (8) 0.2254 (8) 0.2262 (9) 0.2368 (10) 0.2163 (7) 0.2 176 (9) 0.1818 (10) 0.1914 (23) 0.1 194 (38) 0.3863 (39) 0.1535 (10) 0.2198 (10) 0.2016 (10) 0.2153 (15) 0.2101 (15) 0.1840 (16) 0.1054 (10) 0.1545 (10) 0.0879 (10) 0.4213 (10) 0.3616 (10) 0.3633 (10)

0.4807 (22) 0.4792 (26) 0.4193 (24) 0.4028 (23) 0.4445 (31) 0.5594 (37) 0.5794 (31) 0.4299 (23) 0.3285 (33) 0.4723 (29) 0.1497 (14) -0.0418 (16) 0.0248 (17) 0.2219 (16) 0.1110 (22) 0.0113 (19) 0.0880 (19) 0.2600 (20) -0.0069 (29) -0.0055 (27) 0.0450 (24) -0.0104 (25) -0.0824 (25) -0.0252 (28) 0.0297 (35) -0.1209 (28) -0.1782 (31) -0.1674 (33) 0.3504 (32) 0.2503 (27) 0.2164 (21) 0.1393 (27) 0.1267 (30) 0.0765 (32) 0.1631 (39) 0.2324 (23) 0.3047 (32) 0.2386 (36) 0.705 1 (83) 0.0101 (134) 0.0533 (132) 0.7298 (35) 0.7784 (36) 0.5840 (35) 0.6025 (54) 0.7906 (55) 0.6142 (54) 0.0956 (36) 0.9719 (35) 0.9116 (36) 0.0355 (36) 0.1439 (36) -0.0138 (36)

5.9 (7) 5.2 (7) 5.0 (6) 4.4 (6) 6.1 (8) 9.3 (11) 7.5 (11) 5.5 (6) 6.4 (9) 6.6 (8) 4.3 (4) 4.8 (4) 5.8 (4) 5.4 (4) 5.0 (6) 4.6 (5) 4.8 (5) 4.7 (5) 6.1 (8) 5.5 (7) 3.8 (6) 4.7 (6) 5.2 (6) 7.3 (8) 6.1 (11) 5.4 (7) 7.4 (8) 5.8 (9) 6.2 (8) 6.4 (7) 4.0 (5) 5.3 (7) 6.7 (7) 8.7 (9) 8.9 (11) 5.4 (6) 6.6 (8) 9.1 (11) 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0

@) Anisotropic Thermal Parameters (X lo4) of the Heavy AtomsC PI2 613 P23 Pll 022 P33 PI2 013 023 3.0 (5) 6.5 (1) 80.2 (18) -0.3 (3) -3.7 (12) Pdl 33.5 (8) 5.6 (1) 70.2 (16) -2.1 (3) -3.4 (11) 1.9 (4) 37.0 (9) 0.3 (5) 35.2 (8) 5.8 (1) 71.8 (16) -1.3 (3) -2.9 (11) 7.9 (4) Pd2 34.4 (9) 6.6 (1) 67.9 (16) -0.5 (3) 5.0 (11) 35.2 (8) 6.1 (1) 80.3 (19) -0.9 (3) -5.3 (11) 2.7 (5) Pd3 41.4 (9) 6.1 (1) 64.2 (16) 0.1 (3) -6.0 (11) -0.8 (5) Pll

Agl Ag2 Ag3

P22

033

(I Multiplier used. Only 1.1 CHCl, rather than 2 CHCl, as indicated by elemental analyses was observed on an electron density difference map. The p i ] are defined by T = exp[-(h2p,l + kZPa2+ l a p , , + 2hkpI2 + 2hlp1, + 2 k l p Z 3 ) ] .

tal-packing forces, which may also be the reason for the different Ag-0 and Ag-N bond lengths in the three Ni(6HCQD)*- units. Configuration of the Metal Cluster. The geometry of the metal atoms in the molecule can be described best as a trigonal bipyramid (Tables V and VI) as shown in Figure 4. The deviation of Ag2 from the least-squares plane defined by Nil-Ni2-Ni3-Ag2 is only 0.004 A. The Agl-Ag2-Ag3 chain is almost linear 178.1 (2)O. The angle between the AglAg2-Ag3 line and the Nil-Ni2-Ni3 least-squares plane is

8 9 . 7 O , indicating that the chain of silver atoms is nearly perpendicular to the plane. It is worthwhile to note that Agl and Ag3 are about equidistant (-4.7 A) from the three nickel atoms. However, they are too far for direct interaction. The center Ag2 is closer to the nickel atoms, about 3.6 8, away, but is still too far for M-M interactions to occur. The distances between the nickel atoms are listed in Table V with Nil and Ni3 closer to each other. Most interesting are the Agl-Ag2 (3.056 (5) A) and Ag2-Ag3 (3.052 (5) A) distances. By comparison, the Ag-Ag

3126 Inorganic Chemistry, Vol. 19, No. 10, 1980

Ma et al.

Table IIL4 Interatomic Distances (A) for the Ni-Ag and Pd-Ag Structures Nil Ni2 Ni3 Agl-N4 Agl-04 Ag2-04 Ag2-01 Ag3-01 A 3 N1 M G l M-04 M-N2 M-N3 02-03 01-04

2.20 (4) 2.94 (3) 2.48 (3) 2.38 (3) 2.83 (3) 2.15 (4) 1.91 (3) 1.86 (3) 1.85 (4) 1.93 (4) 2.38 (5) 2.31 (4)

2.18 (4) 2.81 (3) 2.50 (3) 2.50 (3) 2.93 (3) 2.18 (4) 1.83 (3) 1.92 (3) 1.90 (3) 1.84 (4) 2.40 (5) 2.34 (4)

2.30 (4) 2.89 (3) 2.54 (3) 2.54 (3) 2.94 (3) 2.20 (4) 1.83 (3) 1.90 (3) 1.85 (3) 1.82 (3) 2.26 (4) 2.41 (4)

Selection from the complete table which is available as supplementary material. each column. Table N.‘ Bond Angles (Deg) for the Ni-Ag and Pd-Ag Structures Nil N12 01-Ag2-04 Ag2-04-Mb Ag2-01-M 01-M-04 01-M-N2 04-M-N3 N2-M-N3 01-M-N3 04-M-N2

56.9 (10) 112.4 (14) 114.6 (13) 75.9 (13) 96.4 (15) 91.6 (15) 96.0 (16) 167.4 (14) 171.3 (16)

55.8 (9) 111.7 (12) 115.2 (13) 77.2 (12) 91.6 (13) 93.2 (14) 98.7 (16) 168.3 (15) 166.5 (13)

Pdl

Pd2

Pd3

2.39 (2) 2.86 (2) 2.44 (2) 2.45 (2) 2.79 (2) 2.20 (3) 2.03 (2) 2.02 (2) 1.99 (2) 2.01 (3) 2.45 (3) 2.59 (2)

2.25 (2) 2.81 (2) 2.47 (2) 2.45 (2) 2.83 (2) 2.22 (2) 2.01 (2) 2.01 (2) 2.00 (2) 1.93 (2) 2.43 (3) 2.54 (2)

2.25 (3) 2.91 (2) 2.45 (2) 2.45 (2) 2.90 (2) 2.32 (3) 1.97 (2) 1.97 (2) 1.98 (2) 2.02 (2) 2.36 (3) 2.49 (3)

Corresponds to the metal atom labeled on the top of

Ni 3

Pd 1

Pd2

Pd 3

56.8 (9) 109.7 (13) 112.3 (13) 80.5 (13) 91.9 (13) 90.4 (14) 97.3 (14) 170.7 (15) 172.0 (14)

63.8 (6) 108.6 (7) 108.2 (7) 79.2 (7) 92.6 (9) 92.2 (9) 96.0 (10) 171.4 (9) 172.0 (9)

62.1 (6) 109.6 (8) 109.9 (7) 78.2 (7) 93.6 (8) 94.1 (9) 94.5 (10) 170.5 (9) 170.4 (9)

60.0 (6) 111.2 (8) 108.4 (7) 78.4 (8) 92.1 (8) 94.9 (9) 94.6 (9) 172.9 (9) 170.6 (8)

a Selection from the complete table which is available as supplementary material. each column.

Corresponds to the metal atom labeled on the top of

Table V.4 Distances between Heavy Atoms (A) Ni-Ag Nil-Ni2 6.609 (9) Nil-Ni3 5.697 (9) Ni2-Ni3 6.535 (10) Agl-Ag2 3.059 (5) Ag2-Ag3 3.052 (7) Ag2-Nil 3.616 (7) Ag2-Ni2 3.668 (8) Ag2-Ni3 3.651 (8)

Pd-Ag Pdl-Pd2 Pd2-Pd3 Pdl-Pd3 Agl-Ag2 Ag2-Ag3 Ag2-Pdl Ag2-Pd2 Ag2-Pd3

6.682 (3) 6.561 (3) 5.600 (4) 3.173 (3) 3.179 (3) 3.638 (3) 3.666 (3) 3.656 (3)

Selection from the complete table which is available as supplementary material. Table VL4 Related Angles (Deg) for the M,Ag, Clusters -

Agl-Ag2-Ag3 Mbl-Ag2-M2 M 1-Ag2-M3 M2-Ag2-M3

178.1 (2) 130.3 (2) 103.2 (2) 126.5 (2)

178.65 (4) 132.38 (9) 100.29 (6) 127.32 (8)

Selection from the complete table which is available as suppleRepresents Ni in column 2 and Pd in column mentary material. 3.

distance in metallic silver is 2.89 A.17Since a Ni-Ni distance of 3.25 A is sufficient to indicate M-M interaction in the stacked Ni(HDMG)215complex, it seems likely that there are interactions between the Ag atoms in the Ni-Ag cluster. The tendency of Ag(1) ions to form linear bonds may also contribute to the linear arrangement of the atoms. Coordination around Ag. The Ag2 atom in the center of the chain is also coordinated to six 0 atoms of three Ni(6HCQD)2- units which act as bidentate ligands coordinating to Ag2 via their 0 1 and 0 4 oxime oxygen atoms, forming three four-membered chelate rings around Ag2 (Figure 3). (17) “Spacings and Structures of Metals and Alloys”; Oxford Pergamon Press: London, 1967; Val. 2. Kim, Y.; Seff, K. J. A m . Chem. Sac. 1978, ZOO, 6989 and references therein.

Figure 4. The trigonal bipyramid arrangement of the metal atoms in Ni-Ag.

The average Ag-0 bond length is 2.49 (3) A, well within the range of Ag-0 bonds (2.15-2.88 A) reported in the literature.18-21 The three Ni(6-HCQD)2- are not arranged symmetrically around Ag2 at 120° angles with respect to each other, but rather the dihedral angles formed between the three least-squares planes Ag2-104-Nil-101, Ag2-204-Ni2-201 and Ag2-304-Ni3-301 are 130.2, 126.7, and 104.3’, respectively. In contrast to Ag2, only N atoms (N1 or N 4 ) from the Ni(G-HCQD)1 ligands are coordinated to Agl and Ag3 to give a trigonal-pyramidal configuration in each case (Figure 3). The average Ag-N bond length is 2.20 (4) A, comparable to other Ag-N bonds (2.11-2.51 A) reported in the literature.19-23 The oxime oxygen atoms 01 and 0 4 are too far (18) Hunt, G. W.; Lee, T. C.; Amma, E. L. Inorg. Nucl. Chem. Lett. 1974, 10, 909. (19) Delourne, P. J. P.; Loiseleur, R. F. H. Acra Crystallogr., Sect. B 1977, B33, 2709. (20) Kuyper, J.; Vrieze, K.; Olie, K. Crysr. Srrucr. Commun. 1976, 5 , 179. (21) Palgaard, G. A. P.; Hazell, A. C.; Hazell, R. G. Acta Crystallogr., Sect. B 1974, 830, 2721. (22) Britton, D.; Chow, Y. M. Acra Crystallogr., Sect. B 1977, 833, 697.

M,Ag, Cluster Complexes of Camphorquinone Dioxime (>2.8 A) from Agl or Ag3 to form Ag-0 bonds. The distances of Agl and Ag3 from the least-squares planes defined by lN4-2N4-3N4 and lN1-2N1-3N1, respectively, are 0.52 A in both cases. Within the unit cell (Figure 2) of Ni-Ag, no intermolecular H bonding is observed. However, molecules tend to pair up through van der Waals interactions between molecules along the twofold screw parallel to the c axis. There are also two sites for CHC1, near each hexanuclear molecule. The distances between the [ N ~ ( c ~ - H C Q D ) ~molecules A~] and solvent sites (>3.4 A) indicate interactions of only the van der Waals type. Description of the Structure [Pd(6-HCQD),Agl3.2CHCI3, Pd-Ag. A single crystal of the Pd-Ag complex prepared by adding aqueous A g N 0 3 to a MeOH/CHCl, solution of Pd(6-HCQD), was chosen for the X-ray structural study. The results of that study showed that Pd-Ag has the same structure as Ni-Ag with Pd(G-HCQD),- units acting as multidentate ligands. The average Pd-N bond length is 1.99 (2) A, which corresponds well with literature values (1.96-2.03 A) for palladium oxime com 1 e ~ e ~ . ~The ~ average , ~ ~ ~Pd-0 , ~ bond ~ , ~ ~ distance of 2.00 (2) is also comparable to those (2.00-2.03 A) observed in other palladium oxime corn pound^.^^ While the average Ag-0 (2.45 (2) A) and Ag-N (2.27 (3) A) bond distances are comparable to those of the Ni-Ag structure, the distances between Agl-Ag2 (3.173 (3) A) and Ag2-Ag3 (3.179 (3) A) are significantly longer. This arises from the larger size of the Pd(I1) ions which move the 6-HCQD- ligands further away from each other in Pd(6-HCQD); as compared to Ni(G-HCQD)T, resulting in longer Ag-Ag distances (-3.17 A). The Agl-Ag2-Ag3 angle is almost linear, 178.6 (4)' (Table VI), and the angle between the Ag chain and the least-squares plane defined by Pdl-Pd2-Pd3-Ag2 is 89.5', very close to the value in the Ni-Ag structure. The average intramolecular H-bonding distance (2.4 1 (3) A) is shorter than the 2.626 A reported for Pd(HDMG)2,15b,'6a but it is longer than that (2.35 (3) A) in the Ni-Ag structure. However, this is not unexpected because the H-bonding distance in M(HDMG), c o m p l e x e ~is ~directly ~ ~ ~ ~proportional to the size of the metal ion. Other bond distances and angles are summarized in Tables I11 and IV. [Ni(6-HCQD)2Ag]3.2.5CHC13, Ni-Ag, and [Pd(6HCQD),Ag],.2CHC13, Pd-Ag. Both the Ni-Ag and the PdAg complexes can be prepared by adding aqueous AgN0, to a CHC13/MeOH solution of the corresponding M(G-HCQD), complex according to

,

8:

~ M ( ~ - H C Q D+ ) Z3Ag+

HZO MeOH,CHCL*

[M(&HCQD)2Ag]3 + 3H' (1) M = Ni2+ or Pd2+ The I3C N M R spectrum of the Ni-Ag complex in CDC13 solvent exhibits twelve peaks for the C atoms. On the basis of assignments made in the I3C N M R spectrum of Ni(6HCQD),,, the four peaks at 153.76, 153.49, 147.42, and 147.31 ppm downfield from Me$i may be assigned to those of the oxime C atoms. The solid-state structure suggests, however, that only two oxime I3C resonances should be observed. Since the Io7Agand '09Ag isotopes have a spin of '/,, spin-spin coupling between C and Ag may occur. However, this possibility may be dismissed because only two peaks at 153.70 and 142.49 ppm are observed for the oxime C atoms (23) Bigoli, F.; Leporati, E.; Pellinghelli, M. A. Cryst. Struct. Commun. 1975, 4, 127. (24) Constable, A. G.; McDonald, W. S.;Sawkins, L. C.; Shaw, B. L. J . Chem. Soc., Chem. Commun. 1978, 1061. ( 2 5 ) Hussain, M. S.; Schlemper, E. 0. Inorg Chem. 1979, 18, 1116. (26) Dyressen, D. Suen. Kem. Tidskr. 1963, 618. (27) Chakravorty, A. Coord. Chem. Reu. 1974, 13, 1.

Inorganic Chemistry, Vol. 19, No. 10, 1980 3127

Figure 5. Structure of Ni(a-HCQD)2.

in the similar Pd-Ag complex. It therefore appears that Ni-Ag either has a different structure or is a mixture of structures in solution. The IR spectrum of the Ni-Ag complex in a KBr pellet no longer shows an absorption band at 1690 cm-' corresponding to the oxygen-coordinated oxime v(C=N) vibration found in Ni(6-HCQD)2.2,3 Instead, a new band is observed at 1615 cm-', which is most likely the v(C=N) frequency of the oxime group coordinated to both the Ag and Ni ions. The other u(C=N) absorption, which probably arises from the oxime which is N-coordinated to Ni, remains unchanged at 1560 cm-', as previously reported for Ni(6-HCQD)z.2 The bands at 1605 and 1550 cm-' in the I R spectrum of the Pd-Ag complex in a KBr pellet are very similar to those of Ni-Ag. [Ni(a-HCQD)2Ag].0.5AgN03-Hz0 and [Pd(aHCQD),Agf0.5AgN03. Both complexes can be prepared by adding aqueous AgN0, to a MeOH/CHCl, solution of the corresponding M(Lu-HCQD)~ complex. The difference between the starting material M ( C ~ - H C Q Dand ) ~ M(G-HCQD),, mentioned in an earlier section, is the isomeric form of the HCQD- ligand. In Ni(a-HCQD),, the oxime N atom coordiriated to the metal ion is closer to the bridgehead methyl group, as shown in Figure 5 (compare Figure 1). The reaction of M(a-HCQD), with AgNO, proceeds in a manner very similar to that of M(G-HCQD), (eq 1). In contrast to the Ni-Ag and Pd-Ag complexes, both of the products [Ni(a-HCQD)2Ag].0.5AgN03.H20 and [Pd(aHCQD),Ag].0.5AgN03 obtained from the reaction of M(aHCQD), with A g N 0 , are not soluble in common organic solvents such as alcohols, CHC13,CH,CN, and Me,SO. This low solubility may be the result of the cocrystallization of a hexanuclear metal cluster similar to those of Ni-Ag or Pd-Ag with AgN0,. However, there is no evidence to exclude a structure Ag,[M(a-HCQD),l2NO3 in which only two M(aHCQD)2- units coordinate to the chain of three Ag atoms. The IR spectrum of [Ni(a-HCQD),Ag].O.SAgNO, in a KBr pellet shows absorption bands at 1615 and 1550 cm-' while that of [Pd(cu-HCQD),Ag] .0.5AgN03 exhibits absorptions at 1600 and 1550 cm-I. These v(C=N) vibrational frequencies, also observed in the Ni-Ag and Pd-Ag clusters, may indicate that oxime-bridged metal clusters are indeed present in these compounds as well. Compounds of the type [Ni(aHCQD),Ag13 without AgNO, have not been isolated. [Ni(6-HCQD)2(py)21.CHCI,. In a further attempt to understand the coordination chemistry of Ni(G-HCQD),, pyridine was added to a H20/MeOH/CHC1, solution of Ni(6HCQD)2, and a green paramagnetic complex, [Ni(6HCQD),(py),].CHCl,, was isolated. The molar conductivity of the complex in CH3CN shows that it is nonionic, which suggests that a bis(pyridine) adduct of Ni(G-HCQD), is formed. Its infrared spectrum taken in a KBr pellet shows v(C=N) absorptions at 1610 and 1550 cm-'. These are indeed very similar to those (1615 and 1560 cm-') observed in the Ni-Ag complex. Although it is unlikely that a hexanuclear metal cluster is formed, it may suggest that the trans-N202 coordination around Ni(I1) has changed to ci.s-N202. In an effort to determine if [ N ~ ( c ~ - H C Q D ) ~ ( ~ ~ ) ~ ] . C H C ~ ~ is simply a 2:l adduct of pyridine with trans-N202Ni(6HCQD)*, the UV-visible spectrum of Ni(G-HCQD), in CHClj was studied in the presence and absence of pyridine. In fact, there is no reaction of Ni(G-HCQD), with pyridine since its

Znorg. Chem. 1980. 19. 3128-3131

3128

PY

Figure 6. Proposed structure of [Ni(6-HCQD)2(py)2].CHC13.

absorption a t 576 nm remains unchanged over a period of several days. Also there is no evidence of the 614-nm absorption characteristic of N ~ ( I ~ - H C Q D ) ~Moreover, ( ~ ~ ) ~ . the pyridine solution remains diamagnetic, which suggests that the Ni(G-HCQD), retains its square-planar geometry even in the presence of excess pyridine. These observations strongly indicate that Ni(6-HCQD)2(py)2is not a simple trans adduct of Ni(G-HCQD),, Figure 1. A possible structure for this complex is the one shown in Figure 6 in which the (HCQD-), coordination around the N i is now cis-N202as suggested by the IR results. Further evidence in support of this structure is the fact that addition of A g N 0 3 to a H20/MeOH/CHC13 solution of [Ni(6-HCQD)2(py)2].CHC1, readily yields the Ni-Ag cluster. The solvent (H20/MeOH/CHC13) plays an important role in the preparation of Ni(G-HCQD)2(py)2. Perhaps its high

polarity promotes the isomerization of trans-N202 Ni(6HCQD), to the cis-N202 isomer which then reacts with pyridine. Since our attempts to prepare similar Ni-Ag cluster complexes with Ni(HDMG), and Pd(P-HCQD), (in the ternary solvent system) failed, it becomes evident that N,O-chelation of the ligand to the metal is probably a necessary condition for the formation of these hexanuclear cluster complexes. Acknowledgment. We are grateful to the National Institute of General Medical Sciences (PHS Research Grant No. GM12626) and the U S . Department of Energy, Division of Materials Science, for support of this research. Purchase of the JEOL FX-90Q N M R spectrometer was made possible through a grant from the National Science Foundation. We appreciate a useful suggestion made by a, reviewer on the structure of one of the compounds. Registry No. Ni-Ag, 74744-20-0; Pd-Ag, 74744-21-1; Ni(674498-59-2; Pd(aHCQD)2(py)2,745 11-62-9; N~((Y-HCQD)~A~, HCQD)2Ag,745 11-63-0; Ni(G-HCQD),, 52139-64-7; Pd(G-HCQD),, 72100-35-7; N~(wHCQD)~, 52231-70-6; Pd(PhCN),CI2, 14220-64-5. Supplementary Material Available: Tables of observed and calculated structure factors for [Ni(6-HCQD)2Ag]3.2,5CHC13 and for [Pd(6-HCQD)2Ag]3-2CHC13 and complete tables of interatomic distances and angles and least-squares planes (36 pages). Ordering information is given on any current masthead page.

Contribution from the Department of Chemistry, Queen’s University, Kingston, Canada K7L 3 N 6

Protonation of Dimethylmercury. Complexing Reactions of CH3Hg+ in the Gas Phase JOHN A. STONE,* J. RICHARD M. CAMICIOLI, and MICHAEL C. BAIRD* Received February 26, 1980

The reactions of dimethylmercury have been examined in a high-pressure,field-free, chemical ionization source with methane as the reagent gas. Both CH3Hg+and (CH3)2HgH+are formed by protonation of (CH3),Hg, and both react with (CH3)?Hg to yield (CH3)3Hg2+ as the final stable product. This ion reacts with added aromatic, olefinic, and n-donor bases to yield stable methylmercury adduct ions, CH3HgB+. The order of stability of these complexes parallels that of the protonated analogues BH+. It is suggested that (CH3)3Hg2C and (CH3)*HgH+have similar structures which arise from the attack of the electrophilic CH3Hg+or H+ on the CH3Hg-CH3 u bond. The cleavage of transition metal-carbon u bonds by electrophilic reagents has elicited considerable attention of late.] We have been particularly interested in the cleavage reactions of compounds of the type $-CSHSFe(CO),R with the halogens,2 m e r c ~ r y ( I I ) and , ~ ~ o p p e r ( I 1 and ) ~ have very recently investigated the stereochemistry of the acid (DC1, CF$02D) cleavage of the compounds cis- and trans-(4-methylcyclohe~yl)Fe(C0)~(~~-C~H~).~ Cleavage in the latter cases yields the corresponding monodeuterated hydrocarbons, with retention of configuration, via a mechanism believed to involve direct protonation of a nonbonding metal d orbital, the highest occupied molecular orbital (HOMO). During the course of the acid-cleavage work, there appeared a report on the gas-phase protonation of CH3Mn(CO),, studied with the use of ICR spectrometry.6 Interestingly, the ICR data were interpreted in terms of protonation of the manganese compound a t two sites, either the essentially d orbitals of e and b2 symmetry or the combination of an e orbital and the (1) (2) (3) (4)

Johnson, M . D.Acc. Chem. Res. 1978, 11, 57. Slack, D. A.; Baird, M. C J . Am. Chem. SOC.1976, 98, 5539. Dong, D.; Slack, D. A,; Baird, M. C. Inorg. Chem. 1979, 18, 188. Rogers, W. N.; Page, J. A,; Baird, M. C. Inorg. Chim. Acta 1979, 37,

a , Mn-C u-bonding orbital. It was possible to correlate the proton affinities of the two sites with photoelectron data for the compound, thus demonstrating the possibility of valuable correlations between the solution-phase and gas-phase protonation reactions of volatile organo transition-metal compounds and their gas-phase ionization potentials. W e have therefore initiated a study of the gas-phase chemistry of representative organometallic compounds, utilizing high-pressure mass spectrometry. We report here a chemical ionization study of dimethylmercury, (CH3)2Hg, surprisingly little studied heretofore in spite of its ready availability and high volatility. We also report preliminary results on the formation of complex ions by the electrophilic reactions of the methylmercury cation, CH3Hgf, with a series of donor ligands. Experimental Section A high-pressure, electron-impact ion source patterned on the one described by Kebarle7 was built. It was usually operated in the field-free mode at ambient temperature, but a repeller field was available. Most results were obtained in the continuous-ionization mode, but time-resolved studies could be made with a pulsed electron beam7 The 2-kV beam was pulsed on for 58 ps, and the decay of

1539

(5) Rogers, W. N.; Baird, M. C. J . Organomet. Chem. 1979, 182, C65. (6) Stevens, A. E.; Beauchamp, J. L. J. Am. Chem. SOC.1979, 101, 245.

0020-1669/80/1319-3128$01.00/0

(7) Kebarle, P. “Interactions Between Ions and Molecules”; Ausloos, P., Ed.; Plenum Press: New York, 1975; p 459.

0 1980 American Chemical Society